MTH3241
Past Exam 1
1 Suppose that the number of calls per hour arriving at an answering service follows a Poisson process with parameter λ.
(a) What is the probability that fewer than two calls (i.e. at most one call) come in the first hour?
(b) Suppose that six calls arrive in the first hour. What is the probability that at least two calls arrive in the second hour?
(c) The person answering the phone waits until fifteen phone calls have arrived before going to lunch. What is the expected amount of time that the person will wait?
(d) Suppose it is known that exactly eight calls arrived in the first two hours. What is the probability that exactly five of them arrived in the first hour?
(e) Suppose it is known that exactly k calls arrived in the first t hours. What is the probability that exactly j of them (j ≤ k) arrived in the first s hours (s ≤ t)?
(f) Deduce the conditional mean number of arrivals in the first s hours given that exactly k calls arrived in the first t hours (t ≥ s).
[14 marks]
2 (a) Consider the four-state Markov chain with transition matrix
where q = 1 − p and 0 < p < 1.
i. Represent graphically this Markov chain.
ii. Assume that the chain starts in state 2. Find the absorption probabilities.
(b) Consider a seven-state Markov chain with transition matrix
where q = 1 − p and 0 < p < 1.
i. Give a decomposition of this chain into classes of communicating states. For each recurrent class, state its periodicity and comment on the exis-tence of steady-state probabilities.
ii. Assume that the chain starts in state 1. What is the long-term expected fraction of time that the chain spends in each of the seven states?
iii. Assume that the chain starts in state 4. What is the expected number of transitions until it leaves states 4 and 5 never to return?
[19 marks]
3 Consider a four-state continuous-time Markov chain in which the transition rates are given by
(a) Write down the transition matrix of the corresponding embedded Markov chain as well as the transition rates out of each of the three states.
(b) Obtain the steady-state probabilities of this Markov chain.
(c) What is limt→∞ p32(t)?
(d) It can be shown that p22(t) = 4/1 + 4/3e −4λt. Writing the appropriate backward equation, obtain p12(t).
You may use the fact that the ordinary differential equation y 0 (t)−γy(t) = g(t) has a unique solution given by
[18 marks]
4 Consider a branching process, {Xn, n ≥ 0}, in which X0 = 1 and the offspring distribution is
P(ξ = 0) = p, P(ξ = 1) = q, P(ξ = 2) = q, P(ξ = 3) = p,
where p + q = 1/2 and 0 ≤ p ≤ 1/2.
(a) Find the mean and the variance of Xn.
(b) Find the probability of the population dying out on the second generation.
(c) Obtain the probability of ultimate extinction.
[12 marks]
5 Consider a random walk Xn = ξ1 + . . . + ξn, n ≥ 1, with
P(ξ1 = −1) = P(ξ1 = 1) = p, P(ξ1 = 0) = 1 − 2p,
where 0 < p < 1/2.
(a) Obtain P(X2 = 0) and P(X3 = 0).
The remainder of this question is devoted to generalising these findings.
(b) Obtain the conditional distribution of ξj given ξj ≠ 0; i.e. obtain P(ξj = x|ξj ≠ 0), x = −1, 0, 1.
(c) Obtain the probability that exactly k of ξ1, . . . , ξn are zero (and the remaining n − k of them are non-zero).
(d) Argue that the conditional probability that Xn is zero given that exactly k of ξ1, . . . , ξn are zero (and the remaining n−k of them are non-zero), is the same as the probability that a simple random walk is zero at step n − k. Deduce an expression for P(Xn = 0|k of ξ1, . . . , ξn are zero).
(e) Obtain an expression, as a sum ( . . .), for P(Xn = 0).
[17 marks]
6 Let X1, X2, . . . be a sequence of independent and identically distributed random variables with
P(X1 = −1) = P(X1 = 1) = p, P(X1 = 0) = 1 − 2p,
where 0 < p < 1/2. Define the following processes Mn = X1 + . . . + Xn, for n ≥ 1, with M0 = 0, and Wn = Wn−1 + Xn(1 + Xn−1), with W0 = 0.
(a) Show that Mn is a martingale with respect to the filtration {Fn, n = 0, 1, . . .} generated by the sequence X1, X2, . . ..
(b) Show that Wn is a martingale with respect {Fn, n = 0, 1, . . .}.
(c) Let φ be the moment generating function of X1. Show that e λWn is a martin-gale with respect {Fn, n = 0, 1, . . .} if and only if φ(λ) = φ(2λ) = 1. Deduce that e λWn is not a martingale with respect {Fn, n = 0, 1, . . .}, unless λ = 0.
[10 marks]
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